Content: The data reported in this repository is numerical values of plots reported in Figs. 1 through 3 of article [1].
The excel sheet contains three pages, one dedicated to each figure in [1].

Page Fig 1: 
Liquid-vapor coexistence for the van der Waals equation of state, i.e reduced saturation vapor and liquid densities for each reduced temperature --reduced means normalized by critical state properties. Reference: Obtained using Maxwell equal area construction, Simulation: Obtained via lattice Boltzmann simulation of 1-D liquid column embedded within saturated vapor surrounding.
rho_r : Reduced density, T_r : Reduced temperature

Page Fig 2:
Distribution of density and temperature along the channel, for 2-D thermal Couette flow at Ma=1.6 and Pr. 1.2. Analytical: Obtained using analytical solution as presented in Eq. 4.13 in [2]. Simulation: lattice Boltzmann simulations reported in [1].

Page Fig 3:
Cylindical liquid column interaction with shock at Ma=1.3: Evolution of drop size along x-axis, W, normalized by drop initial diameter D0 over time t, normalized by characteristic time t0 = (D0/u_s)(csv/csl)\sqrt(rhol/rhov). Here u_s is the shock speed, csv and csl the sound speed in vapor and liquid phases and rhol and rhov the densities in liquid and vapor phases. Reyhanian et al. : Simulation data from [3], Igra et al. : Experimental data from [4] and Simulation: lattice Boltzmann simulations reported in [2].

[1] I. Karlin, and S. A. Hosseini, arXiv preprint arXiv:2508.00577 (2025).
[2] S.A. Hosseini, and M. Feinberg, and I. V. Karlin, arXiv preprint arXiv:2510.14712 (2025).
[3] E. Reyhanian, B. Dorschner, and I. V. Karlin, Physical Review E 102, 020103 (2020).
[4] D. Igra and K. Takayama, Report of the Institute of Fluid Science, Tohoku University 13, 19 (2001).
